Dimensioning - Union Collegetchakoa/mer101/Chapter 2... · Dimensioning Features d) Repetitive...
Transcript of Dimensioning - Union Collegetchakoa/mer101/Chapter 2... · Dimensioning Features d) Repetitive...
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Dimensioning
2-4) Dimensioning and Locating Simple Features
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Dimensioning Featuresa) A circle is dimensioned by its diameter
and an arc by its radius using a leader line and a note.
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Exercise 2-6
Circular and rectangular views
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Exercise 2-6Answer questions about the cylindrical and hole features of the part shown.
Find the hole and cylinder.
Which view is considered the circular view and which is considered the rectangular view?
Circular view
Rectangular view
Looking at just the top view, can you tell the difference between the hole and the cylinder?
No
So that the cylinder is not confused with a hole.
Why is the diameter of the hole given in the circular view and diameter of the cylinder given in the rectangular view?
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Dimensioning Featuresb) Holes are
dimensioned by giving their diameter and location in the circular view.
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Dimensioning Featuresc) A cylinder is
dimensioned by giving its diameter and length in the rectangular view, and is located in the circular view.
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Dimensioning Featuresd) Repetitive features or dimensions may
be specified by using the symbol “X”along with the number of times the feature is repeated.→ There is no space between the number of
times the feature is repeated and the “X”symbol, however, there is a space between the symbol “X” and the dimension.
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Exercise 2-7
Dimensioning and locating features
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Exercise 2-7Dimension the object shown.
How do we dimension the hole diameters?
How do we locate the holes?
How do we dimension the cylinder diameters?
How do we dimension the cylinder heights?
Completely dimensioned.
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Dimensioning
2-5) Dimensioning and Locating Advanced Features
Skip advanced topic
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Dimensioning Featuresa) If a dimension is given to the center of a
radius, a small cross is drawn at the center.
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Dimensioning Featuresa) Where the center location of the radius is
unimportant, the drawing must clearly show that the arc location is controlled by other dimensioned features such as tangent surfaces.
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Dimensioning Featuresb) A complete sphere is dimensioned by its
diameter and an incomplete sphere by its radius.
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Dimensioning Featuresc) The depth of a blind hole may be
specified in a note and is the depth of the full diameter from the surface of the object.
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Dimensioning Featuresd) If a hole goes completely through the
feature and it is not clearly shown on the drawing, the abbreviation “THRU” follows the dimension.
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Dimensioning Featurese) If a part is symmetric, it is only necessary
to dimension to one side of the center line of symmetry.
Symmetry symbol
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Dimensioning Featuresf) Counterbored holes
Drill DIA
C’Bore DIA
C’Bore depth
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Dimensioning Featuresf) If the thickness of the material below the
counterbore is significant, this thickness rather than the counterbore depth is given.
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Application Question 2-1What do you think a counterbored hole is used for?
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Dimensioning Featuresg) Spotfaced Holes: The difference between
a C’BORE and a Spotface is that the machining operation occurs on a curved surface.
Notice that the depth can not be specified in the note.
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Dimensioning Featuresh) Countersunk Holes
Drill DIA
Drill Depth
C’Sink DIA
C’Sink angle
Space
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Application Question 2-2What do you think a countersunk hole is used for?
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Dimensioning Featuresi) Chamfers: Dimensioned by a linear
dimension and an angle, or by two linear dimensions.
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Dimensioning Featuresi) Chamfers: Dimensioned by a linear
dimension and an angle, or by two linear dimensions.
Space
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Application Question 2-3What do you think a chamfer is used for?
Safety.
Improve engagement of mating parts.
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Drawing NotesDrawing notes give additional information that is used to complement conventional dimension. → manufacturing requirements → treatments and finishes → blanket dimensions (e.g. size of all rounds
and fillets on a casting or a blanket tolerance).
The note area is identified with the heading “NOTE:”.
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Dimensioning
2-6) Dimension Choice
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Dimension ChoiceDimension placement and dimension text influences the manufacturing process used to make the part. → Manufacturing process should not be
specifically stated on the drawing.
Choose dimensions based on function first then manufacturing.
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Units and Decimal Placesa) Decimal dimensions should be used for
all machining dimensions.→ You may encounter a drawing that specifies
standard drills, broaches, and the like by size.
→ For drill sizes that are given by number or letter, a decimal size should also be given.
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Units and Decimal Placesb) Metric dimensions are given in ‘mm’ and
to 0 or 1 decimal place (e.g. 10, 10.2). → When the dimension is less than a
millimeter, a zero should proceed the decimal point (e.g. 0.5).
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Units and Decimal Placesc) English dimensions are given in ‘inches’
and to 2 decimal places (e.g. 1.25). → A zero is not shown before the decimal
point for values less than one inch (e.g. .75).
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Locating Features Using Datums
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Locating Features Using DatumsHow do we choose which surface will be a datum feature?
Good datum features are: → functionally important surfaces → mating surfaces → big enough to permit its use in
manufacturing the part
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Locating Features Using DatumsIn a class setting, do we always know the function of the part?
We need to make an educated guess as to the function of the part.
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Locating Features Using Datumsa) Datum dimensioning is preferred over
continuous dimensioning.
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Locating Features Using Datumsb) Dimensions should be given between
points or surfaces that have a functional relation to each other→ Slots, mating hole patterns, etc...
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Application Question 2-4Why is the distance between the two holes functionally important?
If the hole pattern mates with 2 pins or bolts, the distance between the holes is more important than the distance from the edge to the second hole.
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Dimension AccuracyThere is no such thing as an "exact" measurement. → Every dimension has an implied or stated
tolerance associated with it. → A tolerance is the amount a dimension is
allowed to vary.
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Exercise 2-9
Dimension Accuracy
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Exercise 2-9Which dimensions have implied tolerances and which have stated tolerances?
Implied StatedImplied
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Exercise 2-9Does the arrow indicate an increasing or decreasing accuracy?Increasing
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Exercise 2-9Write down the range in which the dimension values are allowed to vary.> 0.5< 1.5
> 0.95< 1.05
0.9991.001
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Rounding OffThe more accurate the dimension the more expensive it is to manufacture. → To cut costs it is necessary to round off
fractional dimensions.
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Rounding OffHow do we round off? → Let’s round off to the second decimal place.
1.125
2nd decimal place 3rd decimal place
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Rounding OffIf the third decimal place number is:→ less than 5, we truncate after the second
decimal place.
1.123 1.12
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Rounding OffIf the third decimal place number is:→ greater than 5, we round up and increase
the second decimal place number by 1.
1.126 1.13
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Rounding OffIf the third decimal place number is:→ exactly 5, whether or not we round up
depends on if the second decimal place number is odd or even. If it is odd, we round up and if it is even, it is kept the same.
1.165 1.16
1.135 1.14
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Exercise 2-10
Rounding Off
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Exercise 2-10Round off the following fractions to two decimal places according to the rules stated above.(5/16) .3125 →
(5/32) .1562 →
(1/8) .125 →
(3/8) .375 →
.31
.16
.12
.38
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Cumulative TolerancesContinuous dimensioning has the disadvantage of accumulating error. → It is preferable to use datum dimensioning to
reduce error buildup.
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Cumulative TolerancesWhat is error build up?→ e = individual dimension error
x.e 3x.e
x.e + x.e + x.e = 3x.3e
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Exercise 2-11
Dimension Choice
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Exercise 2-11List the dimensioning mistakes and then dimension the object correctly.
What are the 5 dimensioning mistakes?
1 & 2) 2 decimal places / No leading zero
4) Symbol / Decimal
3) Use datum dimensioning
5) Don’t dim. hidden features
Correctly Dimensioned
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Exercise 2-12
Dimensioning 1
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Exercise 2-12Dimension the following object using proper dimensioning techniques.
Did we need the right side view?
Notice the datum features that were used.
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Exercise 2-13
Dimensioning 2
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Exercise 2-13Dimension the following object using proper dimensioning techniques.
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Exercise 2-14
Dimensioning 3
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Exercise 2-14Dimension the following object using proper dimensioning techniques.
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Exercise 2-15
Dimensioning 4
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Exercise 2-15Dimension the following object using proper dimensioning techniques.
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Dimensioning
The End